CN217293463U - Linear injection-blowing and rotation-rotation integrated plastic bottle packaging equipment - Google Patents

Abstract

The utility model discloses a orthoscopic is annotated and is blown number and revolve integrative plastic bottle equipment for packing, it is through being arranged that bottle base forming device, bottle type forming device, electron number device, spiral cover device and send the lid device are the orthoscopic, accomplishes the in bank bottle base back of moulding plastics at bottle base forming device, and annular conveyor follows take out in bank bottle base among the bottle base forming device and transport, through the several bottling links of the blowing bottle link of bottle type forming device, electron number device and the spiral cover of spiral cover device in proper order and seal the link, form output behind the in bank shaping product at last, and then accomplish the preparation of whole product. The whole plastic bottle manufacturing process, the conveying process, the counting and bottling process and the cap screwing sealing process are simple and single in driving mode, only the annular conveying device is kept to continuously operate, interference among all process links is few, limitation is few, and the row-by-row multi-row or even multi-row same-batch production of row-by-row packaged products can be easily realized.

Description

Linear injection-blowing and rotation-rotating integrated plastic bottle packaging equipment

Technical Field

The utility model relates to a plastic bottle shaping technical field especially relates to a orthoscopic is annotated and is blown number and revolve integrative plastic bottle equipment for packing.

Background

Plastic bottles are a commonly used container, and medical liquid containers, medical powder containers, medicine containers, beverage containers, seasoning containers, and the like are widely used, and thus the demand thereof is enormous. At present, plastic bottles suitable for solid particulate products are mostly produced by the following process: firstly, the plastic particles are hot-melted and injected into bottle blanks, then the bottle blanks are stored, the bottle blanks are heated and blown into bottle shapes by a bottle blowing machine, then the bottle blanks are stored, and finally, the filling and packaging of solid particle products in the bottles are completed by a particle counting machine, a cap screwing machine and other equipment. Based on the production process, the preform injecting machine, the bottle blowing machine, the pellet counting machine, the cap screwing machine and the like are independently arranged, conveying rails are required to be laid among the devices to transfer the bottle blanks or the plastic bottles, the occupied area is large, the bottle blanks and the plastic bottles are stored in a large space, and the bottle blanks or the plastic bottles are easily polluted in the storage process. In addition, the middle bottle washing link is added, so that water resources and energy are wasted, operators are increased correspondingly, and the production cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model provides a straight-line type is annotated and is blown number and revolve integrative plastic bottle equipment for packing to each link of solving the current plastic bottle production technology who is applicable to the solid particle product adopts solitary machine to produce the technical problem that area is big, manufacturing cost is high that exists.

According to one aspect of the utility model, a linear injection-blowing-counting-screwing integrated plastic bottle packaging device is provided, which comprises a bottle blank forming device, a bottle-shaped forming device, an electronic counting device, a cap screwing device and a cap conveying device which are arranged in a linear way in sequence, the bottle blank forming device is used for forming rows of bottle blanks through injection molding, the bottle type forming device is used for blow molding the rows of bottle blanks into rows of plastic bottles, the electronic counting device is used for counting and bottling the plastic bottles in rows, the cap screwing device is used for screwing and sealing the plastic bottles in rows, the cap conveying device is used for conveying packaging caps to the cap screwing device, and the linear injection-blowing-number-screwing integrated plastic bottle packaging equipment further comprises an annular conveying device which is used for translating the rows of bottle blanks output by the bottle blank forming device and outputting formed products after the rows of bottle blanks sequentially pass through the bottle type forming device, the electronic particle counting device and the cap screwing device.

Further, several devices of electron include storage hopper, vibration material feeding unit and count unloader, the output of storage hopper is connected to vibration material feeding unit's input, and vibration material feeding unit's output is connected to count unloader's input, and count unloader's output is laid towards several bottling stations.

Furthermore, the vibration feeding device and the counting blanking device are correspondingly arranged with the plurality of bottling stations one by one.

Further, the cap screwing device comprises a first cap screwing power mechanism, a second cap screwing power mechanism, a cap screwing slide rail, a cap screwing connecting plate, a cap taking rod, a third cap screwing power mechanism and a cap screwing frame, wherein the fixed end of the first cap screwing power mechanism is arranged on the cap screwing frame, the movable end of the first cap screwing power mechanism is connected with the fixed end of the second cap screwing power mechanism, the cap screwing connecting plate is respectively connected with the movable end of the second cap screwing power mechanism and the cap taking rod, the cap screwing slide rail is arranged on the cap screwing frame, the cap screwing connecting plate is in sliding fit with the cap screwing slide rail, the first cap screwing power mechanism and the second cap screwing power mechanism are used for driving the cap screwing connecting plate to slide up and down along the cap screwing slide rail, gears are sleeved on the output ends of the cap taking rod and the third cap screwing power mechanism respectively, and adjacent gears are meshed with each other, and the third cap screwing power mechanism is used for driving the gears to synchronously rotate.

Furthermore, the first cap screwing power mechanism and the second cap screwing power mechanism are linear motion mechanisms, and the third cap screwing power mechanism is a rotary motion mechanism.

Further, the bottle blank forming device comprises a blank module, a haversian plate, a haversian mold, a mold opening wedge block, a transition slide rail, a transition mold, a lifting power device, a horizontal power device and an injection core rod, wherein the transition mold is slidably assembled on the transition slide rail, the fixed end of the horizontal power device is installed on the transition slide rail, the power output end of the horizontal power device is connected on the transition mold, the transition slide rail is installed on the power output end of the lifting power device, the blank module is provided with blank forming cavities which are arranged at intervals, the injection core rod and the haversian mold and the blank forming cavities of the blank module are arranged along the vertical direction in a one-to-one correspondence manner, the haversian mold is installed on the haversian plate and is clamped and fixed through an elastic piece on the haversian plate, a conical groove is arranged at the mold closing seam part of the haversian plate, the die opening wedge block is movably matched with the conical groove to jack the haver plate so as to realize the automatic falling of the green body, and the injection molding core rod and the haver plate are respectively movably arranged up and down relative to the blank die assembly.

The cover conveying device comprises a vibration sorting device, a cover conveying plate and a cover conveying power mechanism, the vibration sorting device is used for storing the plastic covers and outputting the plastic covers after sorting in a vibration mode, the cover conveying plate is arranged at the output end of the vibration sorting device, and the power output end of the cover conveying power mechanism is connected with the cover conveying plate and used for driving the cover conveying plate to move so as to receive the plastic covers one by one and convey the plastic covers to the cover screwing device.

Furthermore, a plurality of mechanical arms are uniformly arranged on the annular conveying device at intervals, the distance between every two adjacent mechanical arms is the same as the distance between every two adjacent bottle blanks, and the mechanical arms clamp the bottle blanks from the bottle blank forming device in sequence to convey the bottle blanks along with the rotation of the annular conveying device.

Further, the bottle preform preheating device is arranged between the bottle preform forming device and the bottle-shaped forming device and used for heating the rows of bottle preforms.

Further, the bottle-type forming device includes a bottle blowing frame, a bottle blowing auxiliary plate, a bottle blowing link mechanism, a bottle blowing movable mold plate, a bottle blowing fixed mold plate, a bottle blowing movable mold, a bottle blowing fixed mold, a bottle blowing slide rail, a bottle blowing power mechanism and a blowing component, the bottle blowing fixed mold plate is fixed on the bottle blowing frame, the bottle blowing auxiliary plate and the bottle blowing movable mold plate are slidably assembled on the bottle blowing slide rail, the bottle blowing movable mold plate is located between the bottle blowing auxiliary plate and the bottle blowing fixed mold plate, the bottle blowing link mechanism is located between the bottle blowing auxiliary plate and the bottle blowing movable mold plate, a power output end of the bottle blowing power mechanism is connected to the bottle blowing link mechanism in a liftable manner, the blowing component is disposed on the bottle blowing frame, the bottle blowing movable mold plate is fixed on a surface of the bottle blowing movable mold plate facing the bottle blowing fixed mold plate, the bottle blowing fixed mold plate is fixed on a surface of the bottle blowing fixed mold plate facing the bottle blowing movable mold plate, and the blowing movable blow mold and the blowing fixed blow mold are relatively buckled to form a row of bottle blowing cavities for simultaneously blowing the row of green bodies.

The utility model discloses has following effect:

the utility model discloses a orthoscopic is annotated and is blown number and revolve integrative plastic bottle equipment for packing is through being arranged bottle base forming device, bottle type forming device, electron several devices, spiral cover device and sending the lid device the bottle base forming device accomplishes the back that the in bank bottle base was moulded plastics, annular conveyor follows take out the in bank bottle base among the bottle base forming device and transport, in proper order through the blowing bottle link of bottle type forming device, the several bottling links of electron several devices and the spiral cover of spiral cover device seal the link, form the output behind the in bank shaping product at last, and then accomplish the preparation of whole product. The whole plastic bottle manufacturing process, the conveying process, the counting and bottling process and the cap screwing sealing process are simple and single in driving mode, only the annular conveying device is kept to continuously operate, continuous production operation can be realized, interference among all process links is few, limitation is few, the number of blanks in rows and the number of obtained row of packaged products are not limited by space easily, the row of packaged products can be easily multiple, even the same batch production of multiple rows is realized, therefore, the yield can be improved by times, even dozens of times, and favorable process bases are provided for the large-batch rapid production and manufacturing of various plastic bottle packaged products.

In addition to the above-described objects, features and advantages, the present invention has other objects, features and advantages. The present invention will be described in further detail with reference to the drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention and do not constitute a limitation on the invention. In the drawings:

fig. 1 is a schematic structural view of a linear injection-blowing and number-screwing integrated plastic bottle packaging device according to a preferred embodiment of the present invention.

Fig. 2 is a schematic structural view of a bottle preform preheating device according to a preferred embodiment of the present invention.

Fig. 3 is another schematic structural diagram of the bottle preform preheating device according to the preferred embodiment of the present invention.

Fig. 4 is a schematic structural view of the endless conveyor according to the preferred embodiment of the present invention.

Fig. 5 is a schematic structural view of an injection state of the preform molding apparatus according to the preferred embodiment of the present invention.

Fig. 6 is a schematic top view of the preform molding apparatus according to the preferred embodiment of the present invention.

Fig. 7 is a schematic structural view of a blank output state of the bottle blank forming apparatus according to the preferred embodiment of the present invention after blank forming.

Fig. 8 is a schematic view of the combined structure of the haversian plate and the haversian die according to the preferred embodiment of the invention.

Fig. 9 is a cross-sectional view taken along line K-K of fig. 8.

Fig. 10 is a schematic structural view of a bottle-type forming apparatus according to a preferred embodiment of the present invention.

Fig. 11 is a schematic structural diagram of an electronic particle counting device according to a preferred embodiment of the present invention.

Fig. 12 is a schematic structural view of a cap screwing device according to a preferred embodiment of the present invention.

Fig. 13 is a schematic structural view of the capping device in fig. 12 in a view from direction T.

Fig. 14 is a schematic structural view of a cap feeding device according to a preferred embodiment of the present invention.

Description of the reference numerals

1. A bottle blank forming device; 2. a bottle-shaped forming device; 3. an electronic particle counting device; 4. a cap screwing device; 5. a cap feeding device; 6. an annular conveying device; 7. a bottle blank preheating device; 71. preheating the frame; 72. preheating a fixed template; 73. setting a preheating mold; 74. preheating a movable template; 75. dynamic preheating mould; 76. a preheating power mechanism; 77. preheating the slide rail; 78. preheating the auxiliary plate; 79. preheating the connecting rod mechanism; 61. a manipulator; 101. a blank mold assembly; 102. a haversian board; 103. a haversian mode; 104. opening the die wedge block; 105. a transition slide rail; 106. a transition mold; 107. a lifting power device; 108. a horizontal power plant; 109. injection molding a core rod; 201. a bottle blowing machine frame; 202. a bottle blowing auxiliary plate; 203. a bottle blowing link mechanism; 204. blowing a movable mold plate; 205. bottle blowing fixed mold plate; 206. blowing and blow molding; 207. blowing and blow molding; 208. a bottle blowing slide rail; 209. a bottle blowing power mechanism; 210. an air blowing member; 311. a storage hopper; 312. a vibration feeding device; 313. a counting and blanking device; 411. a first cap screwing power mechanism; 412. a second cap screwing power mechanism; 413. screwing a cover slide rail; 414. screwing a cover connecting plate; 415. taking a cover rod; 416. a gear; 417. a third cap screwing power mechanism; 418. a cover screwing machine frame; 51. a vibration sorting device; 52. sending a cover plate; 53. and a cover feeding power mechanism.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways, which are defined and covered below.

As shown in fig. 1, the preferred embodiment of the present invention provides a linear injection-blow-number-rotation integrated plastic bottle packaging device, which comprises a bottle blank forming device 1, a bottle forming device 2, an electronic counting device 3, a cap rotating device 4 and a cap conveying device 5, wherein the bottle blank forming device 1 is arranged in a linear manner in sequence, the bottle blank forming device 1 is used for injection molding to form rows of bottle blanks, the bottle forming device 2 is used for blow molding rows of bottle blanks into rows, the electronic counting device 3 is used for counting bottles for the rows of plastic bottles, the cap rotating device 4 is used for cap-rotating sealing the rows of plastic bottles, the cap conveying device 5 is used for conveying packaging caps for the cap rotating device 4, and the linear injection-blow-number-rotation integrated plastic bottle packaging device further comprises a device for translating the rows of bottle blanks output by the bottle blank forming device 1 and sequentially passing through the bottle forming device 2, the cap rotating device 3, and the cap conveying device, An annular conveying device 6 for outputting the formed product after the electronic particle counting device 3 and the cap screwing device 4. It can be understood that, by arranging the bottle blank forming device 1, the bottle type forming device 2, the electronic counting device 3, the cap screwing device 4 and the cap feeding device 5 in a straight line, after the bottle blank forming device 1 completes the injection molding of the row of bottle blanks, the annular conveying device 6 takes out the row of bottle blanks from the bottle blank forming device 1 for transportation, and finally forms a row of formed products for output after the blow molding bottle forming link of the bottle type forming device 2, the counting bottle filling link of the electronic counting device 3 and the cap screwing sealing link of the cap screwing device 4 are sequentially carried out, so that the preparation of the whole product is completed. The whole plastic bottle manufacturing process, the conveying process, the counting and bottling process and the cap screwing sealing process are simple and single in driving mode, only the annular conveying device 6 is kept to continuously operate, continuous production operation can be realized, interference among all process links is few, limitation is few, the number of blanks in rows and the number of obtained row packaging products are not limited by space easily, multiple rows of row packaging products and even multiple rows of same-batch production can be easily realized, therefore, the yield can be improved by times, even dozens of times, and favorable process bases are provided for large-batch rapid production and manufacturing of various plastic bottle packaging products.

Optionally, the linear injection-blowing and multi-screwing integrated plastic bottle packaging equipment further comprises a preform preheating device 7 arranged between the preform forming device 1 and the bottle-shaped forming device 2, and the preform preheating device 7 is used for heating rows of preforms. When bottle blowing can be carried out only by preheating the bottle blanks after some plastic particles are made into the bottle blanks, the rows of the bottle blanks can be heated by the bottle blank preheating device 7, and when the bottle blanks can be blown without preheating, the bottle blank preheating device 7 can be omitted.

It can be understood that the preform forming device 1 is located upstream of the annular conveying device 6 in the conveying direction, the preform preheating device 7, the bottle-shaped forming device 2, the electronic counting device 3, the cap screwing device 4 and the cap conveying device 5 are located downstream of the preform forming device 1 in sequence, the preform preheating device 7 and the bottle-shaped forming device 2 are located below the annular conveying device 6, and the electronic counting device 3, the cap screwing device 4 and the cap conveying device 5 are located above the annular conveying device 6. The bottle blank forming device 1 is an independent device, the number of the bottle blank forming device 1 is one, and the number of the bottle blank preheating device 7, the bottle type forming device 2, the electronic bottle counting device 3, the cap screwing device 4 and the cap conveying device 5 can be one, two or more, namely a plurality of continuous preheating stations, a plurality of bottle blowing stations, a plurality of bottle counting bottling stations and a plurality of cap screwing sealing stations can be arranged, for example, two bottle blowing stations can be arranged to synchronously blow two rows of bottle blanks, so that the production efficiency is improved.

Specifically, as shown in fig. 2, the bottle preform preheating device 7 includes a preheating frame 71, a preheating fixed mold plate 72, a preheating movable mold plate 74 and a preheating power mechanism 76, the preheating fixed mold plate 72 is fixed on the preheating frame 71, the preheating movable mold plate 74 is slidably assembled on the preheating frame 71 through a preheating slide rail (not shown), a power output end of the preheating power mechanism 76 is connected with the preheating movable mold plate 74 for driving the preheating movable mold plate 74 to slide on the preheating frame 71 along the preheating slide rail, the preheating fixed mold plate 72 and the preheating movable mold plate 74 are relatively arranged, a fixed preheating mold 73 is fixed on one surface of the preheating fixed mold plate 72 facing the preheating movable mold plate 74, a movable preheating mold 75 is fixed on one surface of the preheating movable mold plate 74 facing the preheating fixed mold plate 72, and the fixed preheating mold 73 and the movable preheating mold 75 are relatively fastened to form a preheating station. In the preheating station, when the fixed preheating mold 73 and the movable preheating mold 75 are in an open state, the annular conveying device 6 brings the rows of bottle blanks into the fixed preheating mold 73 and stops running, then the preheating movable mold plate 74 is matched in place along the preheating slide rail under the action of the preheating power mechanism 76, the movable preheating mold 75 is buckled with the fixed preheating mold 73, and then heating media with preset temperature are respectively introduced into heating medium circulation channels in the matrixes of the movable preheating mold 75 and the fixed preheating mold 73, so that the bottle blanks are preheated; after the preheating for the preset time, the preheating power mechanism 76 retracts and drives the preheating movable mold plate 74 to open the mold, and the annular conveying device 6 continues to operate to prepare for entering the next process. The preheating power mechanism 76 may be a cylinder, an oil cylinder, a telescopic motor, a gear train driving mechanism, or the like. It can be understood that the number of the preheating cavities formed on the fixed preheating die 73 and the movable preheating die 75 is consistent with the number of the bottle preform forming cavities of the bottle preform forming device 1, and the preheating cavities are used for synchronously heating the rows of bottle preforms.

It can be understood that, as shown in fig. 3, as an alternative, the bottle blank preheating device 7 includes a preheating frame 71, a preheating fixed mold plate 72, a preheating movable mold plate 74, a preheating power mechanism 76, a preheating auxiliary plate 78, a preheating slide rail 77 and a preheating link mechanism 79, the preheating slide rail 77 and the preheating fixed mold plate 72 are fixedly mounted on the preheating frame 71, the preheating auxiliary plate 78 and the preheating movable mold plate 74 are slidably mounted on the preheating slide rail 77, the preheating movable mold plate 74 is located between the preheating auxiliary plate 78 and the preheating fixed mold plate 72, the preheating link mechanism 79 is located between the preheating auxiliary plate 78 and the preheating movable mold plate 74, a power output end of the preheating power mechanism 76 is connected to the preheating link mechanism 79, the preheating link mechanism 79 can be driven to fold or extend by the telescopic action of the preheating power mechanism 76, when the preheating link mechanism 79 is folded, the preheating movable mould plate 74 and the preheating auxiliary plate 78 are close to each other, and the preheating movable mould plate 74 is far away from the preheating fixed mould plate 72; when the preheating link mechanism 79 is extended, the preheating moving platen 74 and the preheating auxiliary plate 78 are away from each other, and the preheating moving platen 74 is close to the preheating fixed platen 72. The preheating fixed die plate 72 and the preheating movable die plate 74 are arranged oppositely, a fixed preheating die 73 is fixed on one surface, facing the preheating movable die plate 74, of the preheating fixed die plate 72, a movable preheating die 75 is fixed on one surface, facing the preheating fixed die plate 72, of the preheating movable die plate 74, and the fixed preheating die 73 and the movable preheating die 75 are buckled oppositely to form a preheating station. The annular conveying device 6 brings the rows of bottle blanks into the fixed preheating mold 73 and then stops running, then the preheating power mechanism 76 drives the preheating connecting rod mechanism 79 to extend, the preheating movable mold plate 74 is close to the preheating fixed mold plate 72, mold closing is carried out in place, the movable preheating mold 75 is buckled with the fixed preheating mold 73, and then heating media with preset temperature are respectively introduced into heating medium circulation channels in the matrixes of the movable preheating mold 75 and the fixed preheating mold 73 so as to preheat the bottle blanks; after the preheating for the preset time, the preheating link mechanism 79 is driven to fold and contract by the preheating power mechanism 76, so that the movable preheating die 75 and the fixed preheating die 73 are relatively separated and the preheated bottle blanks in rows are exposed, and the preheated bottle blanks in rows are continuously transferred to the bottle-shaped forming device 2 of the next process for bottle blowing through the annular conveying device 6. It is understood that the preheating auxiliary plate 78 may be fixedly mounted on the preheating frame 71, and only the preheating moving platen 74 is driven to slide when the preheating power mechanism 76 drives the preheating linkage 79 to extend or retract.

It can be understood that, as shown in fig. 4, a plurality of manipulators 61 are arranged on the annular conveying device 6 at regular intervals, the manipulators 61 are used for clamping bottle preforms or plastic bottles for transportation, the distance between adjacent manipulators 61 is the same as the distance between adjacent bottle preforms, and as the annular conveying device 6 rotates, the plurality of manipulators 61 sequentially clamp the bottle preforms from the bottle preform shaping device 1 for transportation. The manipulator 61 may be an air-controlled manipulator or an electric-controlled manipulator.

It can be understood that, as shown in fig. 5 to fig. 9, the bottle blank forming device 1 specifically includes a blank mold assembly 101, a havar plate 102, a havar mold 103, an open mold wedge 104, a transition slide rail 105, a transition mold 106, a lifting power device 107, a horizontal power device 108 and an injection core bar 109; the transition die 106 is slidably assembled on the transition slide rail 105, the fixed end of the horizontal power device 108 is installed on the transition slide rail 105, the power output end of the horizontal power device 108 is connected to the transition die 106, and the transition slide rail 105 is installed on the power output end of the lifting power device 107; the blank mold assembly 101 is provided with rows of blank body molding cavities which are arranged at intervals, and the injection molding core rods 109 and the haversian molds 103 are vertically arranged in a one-to-one correspondence with the blank body molding cavities of the blank mold assembly 101; the haversian die 103 is arranged on the haversian plate 102 and is clamped and fixed by an elastic piece on the haversian plate 102, a conical groove is arranged at the die assembly seam of the haversian plate 102, and the die opening wedge block 104 is movably matched with the conical groove to jack up the haversian plate 102, so that the green body automatically falls off; the injection core pin 109 and the havar plate 102 are each movably arranged up and down relative to the blank mold assembly 101. The haversian plates 102 clamp the haversian dies 103 arranged in rows and fall onto the blank die assembly 101, the haversian dies 103 are arranged in one-to-one correspondence with the blank forming cavities of the blank die assembly 101, and the haversian dies 103 stop in the blank forming cavities of the blank die assembly 101; the injection molding core rod 109 falls down and is in sealed splicing fit with the half mould 103, and materials are quantitatively injected into the blank forming cavity; after the material injection is finished, the injection molding core rod 109 vertically rises, then the haversian plate 102 carries the haversian mold 103 to rise, and the blank formed by the haversian mold 103 is removed from the blank forming cavity; the transition die 106 is driven to move to a position between the blank die assembly 101 and the haversian die 103 to stop through the coordinated work of the lifting power device 107 and the horizontal power device 108; the haversian plate 102 carries the haversian mould 103 to collide and contact with the mould opening wedge block 104 in the rising process, and the mould opening wedge block 104 is inserted into the tapered slot of the haversian plate 102, so that the haversian plate 102 is stressed to overcome the elasticity of the elastic part to open and separate the mould, further the haversian mould 103 is opened and separated, the formed green body falls into the mould cavity of the corresponding transition mould 106, the clamping part of the green body formed by the haversian mould 103 is exposed out of the mould cavity, the clamping part of the green body is clamped by the mechanical arm 61, and the integral translation and transfer action of the row of green bodies is realized. Optionally, the injection core rod 109 is connected to the injection molding compound outlet of the injection molding machine via an injection tube. Optionally, the haversian plate 102 and the haversian die 103 are formed by splicing half-edge dies; a sliding shaft is adopted to penetrate through the two half dies of the haversian plate 102, and two ends of the sliding shaft are provided with pre-tightening springs and are positioned and locked by fixing nuts, so that the two half dies of the haversian plate 102 are kept to be tightly abutted; the conical grooves are arranged at the joint positions of the two half dies of the haversian plate 102 and are arranged corresponding to the die-opening wedge blocks 104 up and down, and then the die-opening wedge blocks 104 are inserted into the conical grooves in the rising process of the haversian plate 102, so that the two half dies of the haversian plate 102 are respectively opened with the two half dies of the haversian plate 103, and the free falling action of the blank is completed. Optionally, the inner cavity of the haversian die 103 is conical, so that the blanks automatically correct the position and fall aligned with the central axis of the transition die 106 during the falling process, and the precision of the falling position is ensured, thereby ensuring that the manipulator 61 clamps the row of blanks accurately and stably and integrally translates the row of blanks. Optionally, two ends of the haversian plate 102 are respectively provided with a tapered groove, and the tapered grooves are arranged in one-to-one correspondence with the upper die sinking wedges 104.

It can be understood that, as shown in fig. 10, the bottle-type forming device 2 specifically includes a bottle blowing frame 201, a bottle blowing auxiliary plate 202, a bottle blowing link mechanism 203, a bottle blowing movable mold plate 204, a bottle blowing fixed mold plate 205, a bottle blowing movable mold 206, a bottle blowing fixed mold 207, a bottle blowing slide rail 208, a bottle blowing power mechanism 209 and a blowing part 210, where the bottle blowing fixed mold plate 205 and the bottle blowing slide rail 208 are fixed on the bottle blowing frame 201, the bottle blowing auxiliary plate 202 and the bottle blowing movable mold plate 204 are slidably assembled on the bottle blowing slide rail 208, the bottle blowing movable mold plate 204 is located between the bottle blowing auxiliary plate 202 and the bottle blowing fixed mold plate 205, the bottle blowing link mechanism 203 is located between the auxiliary plate 202 and the bottle blowing movable mold plate 204, a power output end of the bottle blowing power mechanism 209 is connected to the bottle blowing link mechanism 203, the bottle blowing link mechanism 203 can be driven to fold or extend by the telescopic action of the bottle blowing power mechanism 209, and the bottle blowing link mechanism 203 is retracted when the bottle blowing link mechanism is folded, the bottle blowing movable mould plate 204 is far away from the bottle blowing fixed mould plate 205; when the bottle blowing link mechanism 203 extends, the bottle blowing movable mold plate 204 is close to the bottle blowing fixed mold plate 205. The blowing component 210 is arranged on the bottle blowing machine frame 201 in a lifting manner, the blowing movable blow mold 206 is fixed on one surface of the blowing movable mold plate 204 facing the blowing fixed mold plate 205, the blowing fixed blow mold 207 is fixed on one surface of the blowing fixed mold plate 205 facing the blowing movable mold plate 204, and the blowing movable blow mold 206 and the blowing fixed blow mold 207 are relatively buckled to form a row of bottle blowing cavities for simultaneously blowing the row of blanks. When the bottle blowing movable blow mold 206 and the bottle blowing fixed blow mold 207 are in the mold opening state, the annular conveying device 6 integrally translates the rows of bottle blanks from the bottle blank forming device 1 or the bottle blank preheating device 7 to a bottle blowing station between the bottle blowing movable blow mold 206 and the bottle blowing fixed blow mold 207; the bottle blowing power mechanism 209 drives the bottle blowing link mechanism 203 to unfold, and pushes the bottle blowing movable mold plate 204 to drive the bottle blowing movable blow mold 206 to be buckled with the bottle blowing fixed blow mold 207 on the bottle blowing fixed mold plate 205 and fix a green body, at this time, the bottle blowing movable blow mold 206 and the bottle blowing fixed blow mold 207 enclose to form a bottle body forming cavity matched with the appearance of the plastic bottle, the air blowing parts 210 and the bottle body forming cavity are arranged in a one-to-one correspondence manner, each air blowing part 210 is driven by the lifting driving device to fall synchronously and then is respectively inserted into the air blowing openings of the corresponding green bodies, and air is blown through the air blowing openings of the inner green bodies of the air blowing parts 210, so that the green bodies are inflated and expanded all around until the green bodies are completely attached to the inner wall surface of the bottle body forming cavity, and the bottle blowing process of the plastic bottle is completed. Then, the blowing unit 210 is raised, and the bottle blowing power mechanism 209 drives the bottle blowing link mechanism 203 to fold and contract, so that the bottle blowing movable blow mold 206 and the bottle blowing fixed blow mold 207 are separated and opened, and then the formed rows of plastic bottles are carried by the annular conveying device 6 to continue to move integrally to the next process. Alternatively, the blow bottle movable blow mold 206 and the blow bottle fixed blow mold 207 enclose a bottle body forming cavity with a lower opening, and the bottle type forming apparatus 2 further includes a bottoming member (not shown) that is elevatably mounted on the blow bottle rack 201 and is used for forming a bottom shape of the plastic bottle. Alternatively, the bottle blowing auxiliary plate 202 may also be fixed to the bottle blowing frame 201, and the bottle blowing power mechanism 209 drives the bottle blowing link mechanism 203 to move, so as to control the bottle blowing movable blow mold 206 to approach or depart from the bottle blowing fixed mold plate 205. Alternatively, the bottle blowing power mechanism 209 may employ an air cylinder, an oil cylinder, a telescopic motor, a gear train driving mechanism, or the like.

It can be understood that, as shown in fig. 11, the electronic counting device 3 includes a storage hopper 311, a vibration feeding device 312 and a counting and blanking device 313, an output end of the storage hopper 311 is connected to an input end of the vibration feeding device 312, an output end of the vibration feeding device 312 is connected to an input end of the counting and blanking device 313, an output end of the counting and blanking device 313 is arranged towards the counting and bottling station, the storage hopper 311 is used for storing the solid particle product, the vibration feeding device 312 is used for conveying the solid particle product to the counting and blanking device 313 in a vibration manner, and the counting and blanking device 313 is used for conveying the solid particle product into the plastic bottle and controlling the number of solid particles bottled. The vibration feeding device 312 may be a flat vibration feeder, and the solid particle product may be in the form of a sheet, a block, or a granule. It can be understood that the vibration feeding device 312, the counting and blanking device 313 and the counting and bottling stations are correspondingly arranged one by one. After the rows of plastic bottles are translated in place, the vibration feeding device 312 is controlled to act and vibrate to output the granular materials to the corresponding plastic bottles, the granular materials are counted by the counting and blanking device 313 and then output to the corresponding plastic bottles, the counting and blanking device 313 and the vibration feeding device 312 stop working after the counting and blanking device 313 outputs a preset number of granular materials, and counting and bottling are finished. Wherein, the bottling of a plurality of plastic bottles in a row is carried out synchronously. It can be understood that the electronic counting device 3 can synchronously count and bottle two rows of plastic bottles, thereby being beneficial to improving the yield. Of course, the electronic counting device 3 may also count and bottle only one row of plastic bottles simultaneously, and only the left or right structure is retained in fig. 11.

It can be understood that, as shown in fig. 12 and 13, the cap screwing device 4 includes a first cap screwing power mechanism 411, a second cap screwing power mechanism 412, a cap screwing sliding rail 413, a cap screwing connecting plate 414, a cap taking rod 415, a third cap screwing power mechanism 417 and a cap screwing frame 418, a fixed end of the first cap screwing power mechanism 411 is mounted on the cap screwing frame 418, a movable end of the first cap screwing power mechanism 411 is connected with a fixed end of the second cap screwing power mechanism 412, the cap screwing connecting plate 414 is respectively connected with a movable end of the second cap screwing power mechanism 412 and the cap taking rod 415, the cap screwing sliding rail 413 is arranged on the cap screwing frame 418, the cap screwing connecting plate 414 is in sliding fit with the cap screwing sliding rail 413, the first cap screwing power mechanism 411 and the second cap screwing power mechanism 412 are used for driving the cap connecting plate 414 to slide up and down along the cap screwing sliding rail 413, the cover taking rod 415 and the output end of the third cover screwing power mechanism 417 are respectively sleeved with a gear 416, adjacent gears 416 are meshed with each other, and the third cover screwing power mechanism 417 is used for driving the gears 416 to synchronously rotate, so that the cover taking rods 415 are driven to synchronously rotate. Optionally, the first cap screwing power mechanism 411 and the second cap screwing power mechanism 412 adopt linear motion mechanisms such as an air cylinder, an electric telescopic rod and a linear motor, and the third cap screwing power mechanism 417 adopts a rotary motion mechanism such as a motor and a motor. The action process of the cap screwing device 4 is as follows: the row of plastic bottles integrally translates from the electronic counting device 3 to the cap screwing device 4 through the annular conveying device 6 and respectively enters each cap screwing and sealing station, the first cap screwing power mechanism 411 is controlled to drive the second cap screwing power mechanism 412, the cap screwing connecting plate 414 and the cap taking rod 415 to slide downwards, after the cap taking rod 415 slides downwards for a preset distance, the cap taking rod 415 obtains a plastic cap from the cap feeding device 5, then the cap feeding device 5 is withdrawn, at the moment, a preset distance is kept between the lower plane of the plastic cap and the upper plane of the bottle mouth of the plastic bottle, the third cap screwing power mechanism 417 is controlled to drive the cap taking rod 415 to rotate, the second cap screwing power mechanism 412 is controlled to drive the cap screwing connecting plate 414, the cap taking rod 415 and the plastic cap to continuously slide downwards, the bottle cap and the bottle mouth are screwed through the thread matching of the plastic cap and the plastic bottle mouth, and the cap screwing and sealing are finished. Finally, the first cap screwing power mechanism 411 and the second cap screwing power mechanism 412 are controlled to drive the cap screwing connecting plate 414 and the cap taking rod 415 to slide upwards to the initial position, and the third cap screwing power mechanism 417 is controlled to stop working, so as to wait for the cap screwing and sealing operation of the next batch of plastic bottles. The cover taking rod 415 clamps the plastic cover in an interference fit manner, for example, the cover taking rod 415 is a hollow rod, the size of an inner hole of the hollow rod is slightly smaller than the diameter of the plastic cover, and the plastic cover is pressed into the cover taking rod 415 along with the downward movement of the cover taking rod 415. The first cap screwing power mechanism 411, the second cap screwing power mechanism 412, the cap screwing slide rail 413, the cap screwing connecting plate 414, the cap taking rod 415 and the gear 416 are arranged in one-to-one correspondence with the cap screwing and sealing stations. It can be understood that the cap screwing device 4 can simultaneously carry out cap screwing and sealing actions on two rows of plastic bottles, thereby being beneficial to improving the yield. Of course, it is also possible to perform the cap-turning and sealing operations only for one row of plastic bottles simultaneously, and only half of the structure is retained in fig. 12.

It can be understood that, as shown in fig. 14, the cap feeding device 5 includes a vibration sorting device 51, a cap feeding plate 52 and a cap feeding power mechanism 53, the vibration sorting device 51 is used for storing plastic caps and outputting a plurality of plastic caps after sorting in a vibration manner, the cap feeding plate 52 is arranged at an output end of the vibration sorting device 51 and is used for receiving the sorted plastic caps, and a power output end of the cap feeding power mechanism 53 is connected with the cap feeding plate 52 and is used for driving the cap feeding plate 52 to move so as to receive the plastic caps one by one and convey the plastic caps to the cap screwing device 4. When the cap screwing device 4 is located at the highest position, the cap feeding power mechanism 53 drives the cap feeding plate 52 to move, the moving direction is opposite to the conveying direction of the plastic bottles, the cap feeding plate 52 receives the plastic caps output by the vibration sorting device 51 one by one in the moving process, a plurality of grooves are uniformly formed in the cap feeding plate 52 at intervals, the plastic caps output by the vibration sorting device 51 are sequentially fed into the grooves, after the cap feeding power mechanism 53 acts in place, the cap screwing device 4 descends to take out the caps, and then the cap feeding power mechanism 53 drives the cap feeding plate 52 to move back to wait for next plastic cap conveying. The vibration sorting device 51 is an existing vibration tray sorting machine or vibration tray sorting machine, and thus the specific structure and working principle are not described herein again. The cap feeding power mechanism 53 may be an air cylinder, an oil cylinder, a telescopic motor, a gear train driving mechanism, or the like. It will be appreciated that the vibratory sorting apparatus 51, the lid feeding plate 52 and the lid feeding power mechanism 53 are all mounted on a lid feeding frame (not shown).

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. The utility model provides a linear type is annotated and is blown number and revolve integrative plastic bottle equipment for packing which characterized in that, including bottle base forming device (1), bottle type forming device (2), electron several device (3), spiral cover device (4) and send lid device (5) that are the linear type and arrange in proper order, bottle base forming device (1) is used for moulding plastics and forms row bottle base, bottle type forming device (2) are used for being in a row the bottle base blow molding plastic bottle, electron several device (3) are used for carrying out several bottling to the row plastic bottle, spiral cover device (4) are used for carrying out the spiral cover to the row plastic bottle and seal, send lid device (5) to be used for spiral cover device (4) carry the encapsulation lid, linear type is blown number and revolves integrative plastic bottle equipment for packing still including being used for with the row bottle base that bottle base forming device (1) exported translates and passes through in proper order bottle type forming device (2), An annular conveying device (6) for outputting a formed product after the electronic particle counting device (3) and the cap screwing device (4).

2. The linear injection-blowing and number-screwing integrated plastic bottle packaging equipment as claimed in claim 1, characterized in that the electronic number counting device (3) comprises a storage hopper (311), a vibratory feeding device (312) and a counting and blanking device (313), wherein the output end of the storage hopper (311) is connected to the input end of the vibratory feeding device (312), the output end of the vibratory feeding device (312) is connected to the input end of the counting and blanking device (313), and the output end of the counting and blanking device (313) is arranged towards the number bottling station.

3. The linear injection-blowing and number-screwing integrated plastic bottle packaging equipment according to claim 2, characterized in that the vibratory feeding device (312) and the counting and blanking device (313) are arranged in one-to-one correspondence with the number of bottling stations.

4. The linear injection-blow-count-rotation-integrated plastic bottle packaging equipment according to claim 1, wherein the cap-rotating device (4) comprises a first cap-rotating power mechanism (411), a second cap-rotating power mechanism (412), a cap-rotating slide rail (413), a cap-rotating connecting plate (414), a cap-removing rod (415), a third cap-rotating power mechanism (417) and a cap-rotating frame (418), a fixed end of the first cap-rotating power mechanism (411) is mounted on the cap-rotating frame (418), a movable end of the first cap-rotating power mechanism (411) is connected with a fixed end of the second cap-rotating power mechanism (412), the cap-rotating connecting plate (414) is respectively connected with a movable end of the second cap-rotating power mechanism (412) and the cap-removing rod (415), the cap-rotating slide rail (413) is arranged on the cap-rotating frame (418), and the cap-rotating connecting plate (414) is in sliding fit with the cap-rotating slide rail (413), first spiral cover power unit (411) and second spiral cover power unit (412) are used for the drive spiral cover connecting plate (414) are followed spiral cover slide rail (413) slide from top to bottom, all overlap on getting lid pole (415) and the output of third spiral cover power unit (417) and be equipped with gear (416), intermeshing between adjacent gear (416), third spiral cover power unit (417) are used for driving a plurality of gear (416) synchronous rotation.

5. The linear injection-blow-count-rotation integrated plastic bottle packaging apparatus according to claim 4, wherein said first cap-rotation power mechanism (411) and said second cap-rotation power mechanism (412) are linear motion mechanisms, and said third cap-rotation power mechanism (417) is a rotary motion mechanism.

6. The linear injection-blow-count-spin integrated plastic bottle packaging equipment according to claim 1, wherein said bottle blank forming device (1) comprises a blank mold assembly (101), a haversian plate (102), a haversian mold (103), a mold opening wedge (104), a transition slide rail (105), a transition mold (106), a lifting power device (107), a horizontal power device (108) and an injection core rod (109), said transition mold (106) is slidably mounted on said transition slide rail (105), the fixed end of said horizontal power device (108) is mounted on said transition slide rail (105), the power output end of said horizontal power device (108) is connected to said transition mold (106), said transition slide rail (105) is mounted on the power output end of said lifting power device (107), the blank mold assembly (101) has blank forming cavities arranged at intervals in rows, the injection molding core rods (109), the half molds (103) and blank forming cavities of the blank mold assembly (101) are vertically and correspondingly arranged one by one, the half molds (103) are installed on the half plate (102) and are clamped and fixed through elastic pieces on the half plate (102), a tapered groove is formed in a mold closing seam part of the half plate (102), the mold opening wedge blocks (104) are movably matched with the tapered grooves to jack the half plate (102) so as to realize automatic falling of the blanks, and the injection molding core rods (109) and the half plate (102) are respectively arranged up and down movably relative to the blank mold assembly (101).

7. The linear injection-blowing-counting-screwing integrated plastic bottle packaging equipment as claimed in claim 1, wherein the cap conveying device (5) comprises a vibration sequencing device (51), a cap conveying plate (52) and a cap conveying power mechanism (53), the vibration sequencing device (51) is used for storing plastic caps and outputting a plurality of plastic caps after sequencing in a vibration mode, the cap conveying plate (52) is arranged at the output end of the vibration sequencing device (51), and the power output end of the cap conveying power mechanism (53) is connected with the cap conveying plate (52) and used for driving the cap conveying plate (52) to move so as to receive the plastic caps one by one and convey the plastic caps to the cap screwing device (4).

8. The linear injection-blowing-counting-screwing integrated plastic bottle packaging equipment according to claim 1, characterized in that a plurality of manipulators (61) are arranged on the annular conveying device (6) at regular intervals, the distance between adjacent manipulators (61) is the same as the distance between adjacent bottle preforms, and the plurality of manipulators (61) sequentially pick up and convey the bottle preforms from the bottle preform forming device (1) as the annular conveying device (6) rotates.

9. The linear injection-blow-counting-screwing-integrated plastic bottle packaging equipment according to claim 1, further comprising a preform preheating device (7) disposed between the preform forming device (1) and the bottle-type forming device (2) and adapted to heat the rows of preforms.

10. The linear injection-blowing and rotational-integration plastic bottle packaging equipment according to claim 1, wherein the bottle-type forming device (2) comprises a bottle blowing frame (201), a bottle blowing auxiliary plate (202), a bottle blowing link mechanism (203), a bottle blowing movable template (204), a bottle blowing fixed template (205), a bottle blowing movable blow mold (206), a bottle blowing fixed blow mold (207), a bottle blowing slide rail (208), a bottle blowing power mechanism (209), and a blowing part (210), the bottle blowing fixed template (205) is fixed on the bottle blowing frame (201), the bottle blowing auxiliary plate (202) and the bottle blowing movable template (204) are slidably assembled on the bottle blowing slide rail (208), the bottle blowing movable template (204) is located between the bottle blowing auxiliary plate (202) and the bottle blowing fixed template (205), the bottle blowing link mechanism (203) is located between the bottle blowing auxiliary plate (202) and the bottle blowing movable template (204), the bottle blowing mechanism is characterized in that a power output end of the bottle blowing power mechanism (209) is connected to the bottle blowing link mechanism (203), the air blowing component (210) is arranged on the bottle blowing rack (201) in a lifting manner, the bottle blowing movable blow mold (206) is fixed on one surface, facing the bottle blowing fixed mold plate (205), of the bottle blowing movable mold plate (204), the bottle blowing fixed blow mold (207) is fixed on one surface, facing the bottle blowing movable mold plate (204), of the bottle blowing fixed mold plate (205), and the bottle blowing movable blow mold (206) and the bottle blowing fixed blow mold (207) are oppositely buckled to form a row of bottle blowing cavities for simultaneously blowing the row of blanks.

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